DE4017415A1 - LAMP CIRCUIT FOR A HIGH PRESSURE DISCHARGE LAMP FOR VEHICLES - Google Patents

Description

The invention relates to a novel lamp circuit for a high-pressure discharge lamp for vehicles. More in detail NEN is the invention on a novel lamp circuit directed for a high pressure discharge lamp for vehicles, which in addition to a DC booster circuit has a feedback circuit which Output voltage and the output current of the DC voltage Booster circuit determined and a control signal accordingly sends the determination result to the booster circuit where by the light flux from when the discharge lamp is ignited the discharge lamp a nominal level in a remarkably short zen time span can reach. The invention aims significant improvement in the practical application of metal halide lamps, which are now paying attention as a light excite source for vehicle headlights.

There is an increasing need for motor vehicles Improve safety when driving at night and aerody Namely characteristics of the vehicle body to reduce the Fuel consumption. This need also affects the Schein thrower of a motor vehicle; increasing security requires better visual confirmation of the headlights, while improving aerodynamic properties  requires the headlights to be chamfered or com be made more compact and flatter.

Regarding the reduction in fuel consumption Metal halide lamps received more attention as they a much higher light source efficiency and longer Have useful life as halogen lamps.

In the case of a metal halide lamp, an ignition gas (argon etc.), mercury and metal iodide in a glass bulb fills. When a high voltage to a discharge electrode this lamp is put on, it becomes a mercury arc generated after a discharge of the ignition gas was started that is what creates heat. The heat generated evaporates the metal iodide, which dissociates the mercury arc, causing radiation of a strong light flux which has a specific spectrum of the metal.

A conventional lamp circuit for a high pressure discharge lamp which comprises such a metal halide lamp for example, disclosed in Japanese Unexamined Patent publication 62-2 59 391.

To use a high pressure discharge lamp Switching on the DC voltage source includes the open conventional circuit bare a DC voltage source, a step-up converter connected to the voltage source to raise (boost) the tension, one with the upward connected sine wave converter to convert the DC voltage from the step-up converter to a sinusoidal one AC voltage and a start circuit. The feeding one sinusoidal AC voltage at the time of ignition of the Discharge lamp eliminates unstable operation of the Ent charge lamp, which would otherwise probably be caused by a Rectangular AC voltage would be generated. Constructing the  Up converter in the form that it as a controllable equal voltage converter also serves to adjust the setting of the Lamp circuit output voltage safe.

Although the lamp circuit described may allow that a high pressure discharge lamp by a direct current is ignited, it takes time to get a specified hel maintenance after the lamp is initially ignited has been (start-up time), or if the discharge lamp is turned on again after being temporarily off has been switched (restart time). This Disadvantage is fatal for a headlight.

The cause of this problem is as follows. If the discharge starts while the glass bulb of the discharge lamp is cool (this event is referred to as a cold start below), it takes time for the metal iodide to ver in the glass bulb is vaporized, and when the discharge lamp is ignited again after it has been temporarily switched off, the Pressure in the glass bulb after a certain time eighth high, which increases the discharge start voltage becomes. There are also non-negligible external factors such as the ambient temperature.

Accordingly, an object of the invention is to provide it an improved lamp circuit for a vehicle High-pressure discharge lamp, which has the disadvantage described does not have.

To achieve this goal, according to one aspect, the Invention created a lamp circuit, which a DC booster circuit for lifting (boosting) one Input voltage from a DC input terminal comprises to provide an output voltage which is converted into a AC voltage is converted to apply to a high pressure discharge lamp, also a voltage detector circuit  for determining the output voltage of the DC voltage Booster circuit, a current detector circuit for detection of the output current of the DC booster circuit and a control circuit for sending a control signal corresponding to signals from the voltage detector and the Current detector to the output voltage of the DC voltage To control booster circuit, the control circuit together men with the voltage detector and the current detector coupling system for the DC voltage booster circuit bil the.

In the above arrangement according to the invention, the tax signal based on the output voltage and output current the DC booster circuit relies on DC booster circuit fed back to their off to control the output voltage. Accordingly, the lamps Voltage and the current of the discharge lamp controlled appropriately are determined according to various factors such as phy The physical condition of the discharge lamp and the environmental conditions conditions including the ambient temperature, so that the Luminous flux from the discharge lamp quickly a stable close can reach.

According to another aspect of the invention, a lamp circuit, which is a DC booster circuit for raising (boosting) the input voltage from a DC input terminal to a To supply output voltage which converts to an AC voltage is converted to apply to a discharge lamp, further an output voltage detector for determining the output voltage of the DC voltage booster circuit and Ausge ben of a signal corresponding to the difference between the determined output voltage and a reference value, a Output current detector for determining the output current of the DC booster circuit and to output one Signal corresponding to the difference between the determined Output current and a reference value, a control circuit for  Generating a control signal corresponding to signals from the Output voltage detector and the output current detector and for applying the control signal to the DC boosters circuit to control their output voltage, and a Time control device for applying a signal accordingly the output voltage of the DC booster circuit the output current detector after a period of time ent speaking of a turn-off time of the discharge lamp and Add the signal to a signal corresponding to the off output current of the DC voltage booster circuit for the transition to constant power control, so the addition result make constant, thereby igniting the discharge the operation of the lamp starting from a cool state Time control device the transition to constant power control effect that uses the nominal power after through control in such a way that the output chip voltage detector and the output current detector a the nominal performance exceeding performance is supplied.

According to the invention, therefore, at the time of the cold start, after the light emission continues through the control operations is stepped through the output voltage detector and the output current detector in the specified order are specified, that is, the control operations for Supply of a power exceeding the nominal power, control by the operation of the timing device into constant power control mode. Furthermore, the Time of re-ignition of the discharge lamp the output voltage of the DC booster circuit controlled according to the physical condition of the lamp after it has been switched off, which is indicated by the timing device. Accordingly, the light flow from the discharge lamp quickly reach the stable nominal level.

In the following the invention based on one in the drawing shown embodiment described in more detail. In the Show drawing:  

Fig. 1 to 3, an embodiment of a lamp circuit for a vehicle high-pressure discharge lamp according to the invention, and Fig. 1 is a block diagram of the general circuit construction;

Fig. 2 is a circuit diagram of the circuit structure of essential sections;

Fig. 3 is a diagram for explaining the operation of the lamp circuit;

Fig. 4 to 10 another embodiment of a lamp circuit for a discharge lamp for a vehicle according to the invention; in fact

Fig. 4 is a block diagram of the general circuit construction;

Fig. 5 is a circuit diagram of the circuit structure of essential sections;

Fig. 6 is a SchaItbild a low voltage reset circuit;

Fig. 7A is a circuit diagram of a high frequency amplification circuit;

FIG. 7B schematic waveform diagram;

Fig. 8 is a circuit diagram of an ignition circuit and a Zündstartschaltung;

Fig. 9 is a schematic diagram of the time course of currents and voltages of individual circuit components and the light flux from a lamp to explain a control operation; and

Fig. 10 is a graph showing the relationship between output voltage and output current of a DC booster circuit.

A preferred embodiment of a lamp circuit for a high-pressure vehicle discharge lamp according to the invention is described in detail with reference to FIGS. 1 to 3.

In Fig. 1, reference numeral 1 denotes a lamp circuit (lighting circuit) for a metal halide lamp.

This lamp circuit 1 has a battery 2 , which supplies a DC voltage of approximately 12 volts. The battery 2 is connected to a pair of input terminals 3 and 3 'of the lamp circuit 1 .

A DC booster circuit 4 has an input terminal which is connected to the terminal of the battery 2 via a light switch 5 .

A high-frequency booster circuit 6 is provided in the subsequent stage of the DC booster circuit. The booster circuit 6 converts the DC output voltage of the booster circuit 4 into a sinusoidal AC voltage. A push-pull inverter circuit can serve as the Hochfre frequency booster circuit 6 .

A current limiting load and lamp ignition circuit 7 is provided in the subsequent stage of the high-frequency booster circuit. A metal halide lamp 8 is connected to the output terminals of the circuit 7 .

An ignition start circuit 9 is also connected to the current limiting load and lamp ignition circuit 7 in order to deliver a trigger signal to the latter.

A control circuit 10 generates a pulse signal with a duty cycle in accordance with the output voltage of the DC voltage booster circuit 4 and a voltage obtained via a measuring resistor 13 , then sends the pulse signal to the booster circuit 4 to control its output voltage. The output voltage of the booster circuit 4 is determined by resistors 11 and 11 'and a variable resistor 12 which is arranged for voltage division between the output terminals of the booster circuit 4 . The voltage from the measuring resistor 13 is connected to a line which connects the DC booster circuit 4 to the high-frequency booster circuit 6 in order to convert the output current of the booster circuit 4 into a voltage.

When the light switch 5 is closed in the lamp circuit 1 , the ignition start circuit 9 sends a signal to the current limiting load and lamp ignition circuit 7 , so as to generate a trigger pulse which triggers the lamp 8 . Then the control circuit 10 carries out a required booster control for the battery voltage, so that the discharge lamp changes to the normal state.

Essential sections of the lamp circuit 1 are described in detail below.

DC booster circuit

The DC voltage booster circuit 4 , which is designed as a chopper-DC-DC converter, comprises a coil 15 , which is connected to a positive line 14 ver, an n-channel field effect transistor (FET) 16 , a rectifier diode 17 and smoothing capacitor 18th The FET 16 is arranged at the stage following the coil 15 and connected to the positive line 14 and an earth line 14 '. The FET 16 performs its switching operation in response to a control pulse from the control circuit 10 . The anode of the rectifier diode 17 is connected to the drain of the FET 16 on the positive line 16 ; The Glättungskon capacitor 18 is connected to the cathode of the rectifier diode 17 and the ground line 14 '.

In the booster circuit 4 constructed in the manner described, the coil 15 stores energy when the FET 16 becomes conductive in response to a control pulse from the control circuit 10 . When the FET 16 becomes non-conductive, the coil 15 releases the stored energy with the subsequent superimposition of the corresponding voltage on the input voltage, which increases or boosts the DC voltage.

Control circuit

The control circuit 10 includes a voltage calculation area 19 , a current calculation area 20, and a PWM area (pulse width modulation) 21 . The voltage calculation area 19 determines the output voltage from the booster circuit 4 and performs differential amplification; The current calculation area 20 determines a voltage corresponding to the output current from the booster circuit 4 and performs differential amplification. The PWM region 21 it generates a rectangular pulse with a duty cycle corresponding to the signals from the calculation areas 19 and 20 and sends the pulse to the gate of the FET 16 of the booster circuit 4th

Stress calculation range

A differential amplifier circuit 22 is formed from a differential amplifier 24 and a resistor 23 , which are connected in a negative feedback arrangement. A non-inverting input of the operational amplifier 24 of the differential amplifier circuit 22 is connected to the displaceable terminal of the variable resistor 12 of the aforementioned voltage division via a resistor 25 . A resistor 26 is connected to the non-inverting input and the ground line. The inverting input of the operational amplifier 24 is supplied with a predetermined reference voltage (referred to as V ₁ (V)) which is determined by voltage division resistors 27 and 28 .

Current calculation area

An amplifier circuit 29 includes an operational amplifier 31 and a resistor 30 , which are connected in a negative feedback arrangement. The inverting input of the amplifier circuit 29 is connected via a resistor 32 to the end of the measuring resistor 13 , which is located on the side of the capacitor 18 . The non-inverting input of the amplifier circuit 29 is connected to the other end of the measuring resistor 13 . The amplifier circuit 29 serves to amplify the voltage which is generated at the measuring resistor 13 in accordance with the output current of the booster circuit 4 and outputs the amplified voltage.

A low pass filter (LPF) 33 is provided at the amplifier circuit 29 following stage for rectification.

A differential amplifier circuit 34 comprises an operational amplifier 36 and a resistor 35 which are connected in a negative feedback arrangement; The non-inverting input of the circuit 34 is connected to the output terminal of the low-pass filter 33 via a resistor 37 . A resistor 38 is connected to the non-inverting input of circuit 34 and the ground line. A predetermined reference voltage (referred to as V ₂ (V)), which is specified by a variable resistor 39 , is supplied to the inverting input of the circuit 34 .

The current calculation section 20 further includes a capacitor 40 which is connected in parallel with the feedback resistor to slow the response.

PWM area

The PWM region 21 comprises a comparator 41 , an output mode selector 43 and a gate drive circuit 45 . The minus input terminal of the comparator 41 is OR-linked to the outputs of the operational amplifiers 24 and 36 , and its positive input is supplied with a sawtooth voltage from an oscillator (OSC) 42 .

The output mode selector 43 is connected to the output terminal of the comparator 41 to select output signals therefrom. The output signal of the selector 43 is sent to a buffer 44 .

The input of the gate drive circuit 45 is connected to the output of the buffer 44 and its output is connected to the gate of the FET 16 of the booster circuit 4 . The gate drive circuit 45 serves to increase the speed of the switching operation of the FET 16 .

With the structure described, the PWM region 21 generates a pulse signal with a duty cycle corresponding to the output voltages of the differential amplifiers 22 and 34 , which correspond to error amplifiers, and leads the pulse back to the gate of the FET 16 of the booster circuit 4 . Although not shown, a circuit for specifying the maximum value of the duty cycle of this pulse signal is also provided, which is used to control the boost ratio of the booster circuit 4 .

The operation of the lamp circuit is now described ben.

Fig. 3 shows the temporal changes of the output voltage V shows schematically ₀ (V) and output current I ₀ (A) of the DC booster circuit 4, the potential V _e (V) at the output terminals of the operational amplifiers 24 and 36, the lamp current I _L ( A), the lamp voltage V ₁ (V) and the light flow L (lm) of the lamp 8 . The origin of the time axis corresponds to the point in time at which the light switch 5 is closed.

As can be seen from the curves shown in solid lines in FIG. 3, at the time of the cold start, since the lamp voltage V _L is low immediately after the discharge lamp is ignited, the output current I _{0 of} the booster circuit 4 is low. Accordingly, the duty cycle of the pulse signal from the PWM section 21 is adjusted by the amplified output of the differential amplifier circuit 22 to take the maximum value. This increases the output voltage V _{0 of} the booster circuit 4 to a predetermined level and increases the lamp current I _L , whereby the light emission from the lamp 8 is driven.

As the light flux L of the lamp 8 increases, the lamp voltage V _{L increases} , which leads to an increase in the output current I _{0 of} the booster circuit 4 . When this output current I _{0 reaches} a predetermined level corresponding to the reference voltage V _{2 of} the differential amplifier 34 , the duty cycle of the pulse signal from the PWM section 21 is then specified by the amplified output signal of the differential amplifier 34 , so that this duty cycle with an increase in voltage V _e decreases. Consequently, the output voltage V _{0 of} the booster circuit 4 , which has been kept at a high value, gradually decreases with the increase in the output current I ₀ , and the output current I ₀ finally reaches a normal level. Accordingly, the luminous flux L of the lamp rises steeply at the beginning of the lamp lighting and then changes to reach the nominal value.

If the lamp 8 is ignited again after it was temporarily switched off for a few seconds, the glass bulb of the lamp 8 is still hot. As can be seen from the curves indicated by dotted lines, the lamp voltage V _{L is} high immediately after the lamp 8 is re-ignited, and the output current I _{0 of} the booster circuit 4 is high. Consequently, the duty cycle of the pulse signal of the PWM region 21 is small, so that the output voltage V _{0 of} the booster circuit 4 decreases to almost the normal voltage level immediately after the lamp has been ignited; The lamp current I _L undergoes a similar change. The light flow L quickly reaches the nominal flow level.

If the lamp is turned on again a few tens of seconds after it has been turned off, feedback control is performed such that I ₀ , V _e , I _L , V _L and L assume the values shown in FIG. 3 are indicated by the dotted lines between the solid line and the dotted line for the previous two cases.

The lamp circuit 1 performs the control so that the maximum value of the lamp current I _L at the start of lamp 8 ignition at the time of cold start, for which the starting time is particularly important, is specified by the voltage calculation section 19 , and the light emission control for the lamp 8 is then applied to the current calculation section 20 to allow the output current I _{0 of} the booster circuit 4 to quickly reach a predetermined level. This control prevents the start-up time and the restart time from becoming significantly long due to the physical condition of the lamp 8 (the temperature and the internal pressure of the glass bulb, etc.), the environmental conditions such as the ambient temperature or the influence of external causes such as a change in the battery voltage . It is therefore possible to raise the light flow of the lamp to the normal stable state in a short period of time. It is also possible to easily set the maximum value of the lamp current I ₀ at the time of the cold start and to apply a current which is many times higher than the nominal current level of the lamp when the lamp begins to light up. The present lamp circuit can therefore effectively be used for a lamp whose luminous flux increases slowly.

As described above, the lamp circuit comprises one High pressure vehicle discharge lamp of this invention DC booster circuit for raising an input voltage from a DC input terminal to form an output voltage converted into an AC voltage delt, which to apply to a high pressure discharge lamp is a voltage detector to determine the output span of the booster circuit, a current detector for detection the output current of the booster circuit and a tax circuit for applying a control signal according to the Signals from the voltage detector circuit and the current earth tector circuit to the output voltage of the DC voltage Control booster circuit. The control circuit together with the voltage detector and the current detector form a back coupling system for the booster circuit.

In the above arrangement, therefore, the control signal that is on the output voltage and the output current of the DC chip voltage booster circuit is based, returned to this to to control their output voltage. Accordingly, the Lamp voltage and the discharge lamp current are reasonable are controlled according to various factors, for example the physical condition of the discharge lamp and environmental conditions including the ambient temperature so that the Luminous flux from the discharge lamp quickly a stable close can reach; In addition, the ignition control at the DC voltage output stage before the DC voltage change voltage conversion is carried out, thus avoiding that the whole circuit structure becomes complex.

The second preferred embodiment of a lamp circuit for a vehicle discharge lamp according to the invention will now be described in detail with reference to FIGS. 4 to 10. The illustrated embodiment is a lamp circuit for a metal halide lamp for motor vehicles, to which the invention is applied.

In FIG. 4, a lamp circuit 101 has a battery 102 which supplies a DC voltage of 12 volts. The bat terie 102 is connected to the DC input terminals 103 and 103 'of the lamp circuit 101 .

The reference numerals 104 and 104 'denote DC voltage supply lines; A light switch 105 is connected to the positive line 104 .

Upon receipt of a signal from an abnormality detector (which will be described later) when an abnormality occurs in the lamp circuit, a current cut-off relay circuit 106 opens a relay contact 106a arranged in the positive line 104 to supply the power supply voltage to interrupt circuits arranged in the following stages.

A power terminal 107 is provided for withdrawing a power supply voltage via a diode 108 at the stage following the relay contact 106 a; This Netzan circuit voltage B (V) is a control circuit, etc; leads, which will be described later.

A DC booster circuit 109 is provided at the stage following the power cut relay circuit 106 . This booster circuit 109 raises the battery voltage under the control of the control circuit (which will be described later).

A high frequency booster circuit 110 is provided at the stage following the DC booster circuit 109 . This booster circuit 110 converts the DC output voltage of the booster circuit 109 into a sinusoidal AC voltage. A push-pull inverter circuit can serve as the high-frequency booster circuit 110 , for example.

An ignition circuit 111 generates a lamp trigger pulse upon receipt of a signal from an ignition start circuit (which will be described later) at the start of igniting a lamp and applies the pulse signal to the primary winding 112a of the trigger transformer 112 .

AC voltage output lines 113 and 113 'connect the output terminals of the high-frequency booster circuit 110 with AC voltage output terminals 114 and 114 '. The line 113 is connected to a secondary winding 112 b of a trigger transformer 112 , which is provided on the line 113 , while the other line 113 'is connected to a capacitor 115 . The capacitor 115 forms a current limiting load together with the secondary winding 112 b, but also serves to determine the lamp current.

A metal halide lamp 116 with a nominal power of 35 W is connected to the AC voltage output terminals 114 and 114 '.

An ignition start circuit 117 determines whether the lamp 116 is on or not based on the lamp current detected by the capacitor 115 , and provides a signal to generate a trigger pulse signal to the ignition circuit 111 when the lamp is in the non-ignited state.

A control circuit 118 generates a control pulse Ps with a duty cycle corresponding to the output voltage of the DC booster circuit 109 and a voltage applied across a current detection resistor 120 , then sends the signal Ps to the DC voltage booster circuit 109 via a gate drive circuit 121 to control the output voltage of the boost circuit 109 to control. The output voltage of the booster circuit 109 is determined at the beginning of the lighting by voltage dividing resistors 119 and 119 ', which are net angeord between the outputs of the booster circuit 109 . The resistor 120 is connected to a ground line which connects one of the outputs of the booster circuit 109 and an input of the high-frequency booster circuit 110 to convert the output current of the booster circuit 109 into a voltage.

The control circuit 118 , in response to the output voltage of the DC booster circuit 109 obtained by a timing control circuit 122 , changes the control mode to constant current control for the lamp after a period of time which is determined in accordance with the lamp turn-off time after the lamp ignition is started. This control transition is effected because the start time would be longer if the constant current control were carried out immediately after the lamp started to light. This is described in more detail below.

A voltage drop detector 123 for the supplied voltage sends a signal to the control circuit 118 when the voltage at the terminal 107 drops below a predetermined level, whereby the lamp 116 is controlled with a control power below the rated power.

An abnormality detector 124 detects an abnormality of the circuit state from the relationship between the output voltage and the output current of the DC booster circuit 109 . Upon detection of an abnormality, the abnormality detector sends a signal to the power off relay circuit 106 to turn off the power; The abnormality detector 124 has a low-voltage reset circuit 124 a, which sends a signal to the power cut-off relay circuit 106 to turn off the lamp when the battery voltage becomes abnormally low, so as to keep the lamp lit. When the battery voltage is restored to a level equal to or above the predetermined level, the lamp ignition process starts again.

Significant sections of the lamp circuit 101 are described in detail below.

DC booster circuit

The DC booster circuit 109 , which is formed by a chopper DC-DC converter, comprises a coil 125 connected to the positive line 104 , an N-channel FET 126 , a rectifier diode 127 and a smoothing capacitor 128 . The FET 126 is arranged at the stage following the coil 125 and is connected to the positive line 104 and the ground line 104 '. The FET 126 performs its switching operation in response to a control pulse Ps sent from the control circuit 118 by the gate drive circuit 121 ; The anode of this rectifier diode 127 on the positive line 104 is connected to the drain of the FET 126 . The smoothing capacitor 128 is connected to the cathode of the rectifier diode 127 and the ground line 104 '; In the DC voltage booster circuit, the coil 125 stores energy when the FET 126 becomes conductive in response to the control pulse Ps from the control circuit 118 via the gate drive circuit 121 . When the FET 128 becomes non-conductive, the coil 125 releases the stored energy with the subsequent superimposition of the corresponding voltage on the input voltage, which increases the DC voltage.

Tax area

An output voltage detector 129 determines the output voltage of the DC booster circuit 109 via the voltage dividing resistors 119 and 119 ', compares the determined voltage with a predetermined reference value and outputs the voltage difference as an error signal.

The non-inverting input of an operational amplifier 130 , which serves as an error amplifier, is connected between the voltage dividing resistors 119 and 119 'via a resistor 131 , and its inverting input is supplied with a predetermined reference voltage V ₁ (V) which is generated by the voltage dividing resistors 132 and 132 ' is specified; A predetermined voltage + Vcc (V) from a power supply circuit (not shown) is applied to one end of the resistor 132 .

A feedback resistor 133 is connected to the output and to the non-inverting input of the operational amplifier 130 .

An output current detector 134 determines the output current of the DC booster circuit 109 as a value converted into a voltage by the current detection resistor 120 , compares the determined value with a predetermined reference value, and outputs the voltage difference as an error signal.

An amplifier circuit 135 is formed by an operational amplifier 137 and a resistor 136 , which are connected in a negative feedback arrangement. The non-inverting input of operational amplifier 137 is connected via a resistor 138 to one end (on the ungrounded side) of resistor 120 and its inverting input is grounded via a resistor 139 .

The non-inverting input of an operational amplifier 140 , which serves as an error amplifier, is connected via a resistor 141 to the output of the operational amplifier 137 , and its inverting input is supplied with a reference voltage V ₂ (V) by a reference voltage generator 143 .

A feedback resistor 142 connects the output and the in-going input of operational amplifier 140 .

The reference voltage generator 143 comprises a resistor 144 , a variable resistor 145 and a resistor 144 ', which are connected in series, and a voltage buffer 146 , which stood the voltage between the variable opponent 145 and the resistor 144 '. The output voltage of the voltage buffer 146 is input to the non-inverting input of the operational amplifier 140 through a resistor 147 . At one end of resistor 144 , a predetermined voltage + Vcc is applied from the power supply circuit (not shown).

Timing circuit

The timing control circuit 122 is provided to ensure a transition to constant power control after a period of time corresponding to the lamp turn-off time after the lamp has started to ignite. This timing control circuit 122 comprises an active switching device and a time constant circuit.

The collector of an npn transistor 148 is connected to the positive output of the DC booster circuit 109 , and its emitter is connected to the non-inverting input of the operational amplifier 140 via a resistor 149 .

The base of transistor 148 is connected to the anode of a diode 150 , the cathode of which is grounded by a capacitor 151 (its electrostatic capacitance being denoted by C ₁₅₁ ).

A resistor 152 (with a resistor R ₁₅₂ ) is connected to the base and the collector of the transistor 148 , and a resistor 153 (with a resistor R ₁₅₂ ) is connected to the cathode of the diode 150 and the collector of the transistor 148 .

PWM area

The PWM region 154 comprises a comparator 155 which compares the input voltage with a sawtooth voltage from an oscillator 156 . Based on the comparison result, the PWM area 154 generates the control pulse Ps with a duty cycle that is determined according to the input voltage. More specifically, the negative input of comparator 155 is connected to the outputs of operational amplifiers 130 and 140 and its positive input is connected to the output of oscillator 156 . The output signal of the comparator 155 is sent to the gate drive circuit 121 through a buffer 157 . With the structure described, the PWM section 154 generates the control pulse Ps with a duty cycle corresponding to the output voltage of the differential amplifier 130 or 140 and leads the pulse back to the gate of the FET 120 of the DC booster circuit 109 , thereby controlling its output voltage. Although not shown, a circuit for specifying the maximum value of the duty cycle of this pulse signal is also provided.

The voltage drop detector 123 changes a reference voltage V ₂ in the output current detector 134 according to a decrease in the power supply voltage B to control the voltage applied to the lamp 116 .

The voltage drop detector 123 includes a zener diode 158 and a voltage buffer 160 . The cathode of the Zener diode 158 is connected to a power supply terminal 107 , and its anode is grounded through resistors 159 and 159 '. The output terminal of the voltage buffer, which receives the voltage between the resistors 159 and 159 ', is connected to the cathode of a diode 161 . The anode of this diode 161 is connected via a resistor 162 between the variable resistor 145 and resistor 144 'of the reference voltage generator 143 .

The low-voltage reset circuit 124 a receives the power supply voltage from the positive line 104 to determine a decrease in the battery voltage.

A power supply terminal 163 is connected via a diode 164 to the positive line at the stage following the light switch 105 .

The circuit 124 a comprises a resistor 165 , a Zenerdi ode 168 and a comparator 169 . One end of the opposing stand 165 is connected to the power supply terminal 163 , and its other end is geer det via resistors 166 and 167 . The cathode of zener diode 168 , which is connected in parallel with resistors 166 and 167 , is connected between resistors 165 and 166 , and its anode is grounded. The negative input of the comparator 169 is connected via a resistor 170 between the resistors 166 and 167 , and its positive input is supplied with a voltage which is obtained by dividing the voltage applied to the power supply terminal 163 by means of voltage dividing resistors 171 and 172 .

The output signal of the comparator 169 is supplied to the switching relay circuit 106 .

High frequency booster circuit

A self-energizing push-pull inverter using the opposite operations of two FETs as shown in FIG. 7A is used as the high frequency booster circuit 110 .

One end of a choke coil 173 is connected to the positive output terminal of the DC booster circuit 109 , and its other end is connected to the center tap of a primary winding 174 a of a transformer 174 .

The source connections of two n-channel FETs 175 and 176 are connected to the ground line 104 'via a resistor 120 for current determination. The drain of the FET 175 is connected to one end of the primary winding 174 a of the transformer 174 , while the drain of the other FET 176 is connected to that at the end of the primary winding 174 a.

One end of a feedback winding 177 is connected to the gate of the FET 176 via a resistor 178 and the other end is connected to the gate of the FET 175 via a resistor 179 .

A capacitor 180 and zener diodes 181 connected in opposite bias directions are provided between the gate and source of the FET 175 . A capacitor 180 'and Zener diodes 181 ', which are also connected in opposite bias directions, are provided between the gate and the source of the FET 175 . The Zener diodes 181 and 181 'are provided to protect against surge voltages.

Constant current diodes 182 and 182 'serve to make a bias voltage for the FETs 175 and 176 constant to control the timing of the switching operation, thereby reducing the power loss. The diode 182 is inserted between the gate of the FET 175 and the end of the choke coil 173 , which is connected to the primary winding 174 a of the transformer 174 . The other diode 182 'is inserted between this end of the choke coil 173 and the gate of the FET 176 .

Resistor 183 is connected to the gate and source of FET 175 . A resistor 183 'is connected to the gate and source of the FET 176 .

A capacitor 184 is connected to the two ends of the primary winding 174 a of the transformer 174 , and a capacitor 185 is connected to the two ends of a secondary winding 174 b.

In the thus-constructed high-frequency booster circuit 110, the control is performed for switching the FETs 175 and 176 in the entge gengesetzten directions through the feedback winding 177 through, in order in this way a sinusoidal output clamping voltage to be supplied by the transformer 174th

Fig. 7B shows the voltage waveforms of the individual regions in the high frequency booster circuit 110. A in the figure shows the input voltage V _IN and the voltage V ₁₇₃ at the stage following the choke coil 173 , and B shows the bias potential V _B (with dashed lines Line) and the gate potential V _{G of} the FET 175 (or 176 ).

In the circuit described above, the bias voltage applied to FETs 175 and 176 is removed from the stage following choke coil 173 to prevent a fluctuation in the bias voltage from making FETs 175 and 176 difficult to turn off, resulting in both FETs can be switched on at the same time. Such a problem would cause the vibration to stop and damage the FETs due to the resulting overcurrent.

This is described in more detail. The bias voltage to be applied to the FETs 175 and 176 is taken from the stage following the choke coil 173 by the constant current diodes 182 and 182 'and the resistors 183 and 183 ', so that the voltage V _{173 has} a waveform which is a completely lig rectified sinusoidal waveform. Therefore, the waveform of the bias potential V _{B has} a wave trough corresponding to the wave troughs of the voltage V ₁₇₃ , so that the bias potential V _B temporarily drops, causing the FETs to be in an OFF state. This effect prevents both FETs from being in an ON state due to a change in the input voltage V _IN , thereby ensuring stable oscillation.

Ignition circuit and ignition start circuit Ignition circuit

The primary winding 112 a and the secondary winding 112 b of the trigger transformer 112 are connected at one end to each other, and the common end is connected to an output of the high-frequency booster circuit 110 . The other end of the secondary winding 112 b is connected to the AC voltage output terminal 114 , and the other end of the primary winding 112 a is connected to the anode of a thyristor 186 .

A capacitor 187 and a resistor 188 are connected in parallel between the gate and the cathode of the thyristor 186 .

The anode of a zener diode 189 is connected to the gate of thyristor 186 through a resistor 190 , and its cathode is connected to AC output line 113 .

One end of a resistor 191 is connected to the cathode of zener diode 189 and the other end is connected to the cathode of thyristor 186 .

A capacitor 192 is arranged in parallel with the resistor 191 .

Ignition start circuit

The anode of a diode 193 is connected to the AC voltage output terminal 114 ', and its cathode is connected to the AC voltage output line 113 ' via a resistor 194 and a capacitor 195 . Diode 193 , resistor 194 , and capacitor 195 are connected in parallel with capacitor 115 .

A zener diode 196 is connected to the capacitor 195 in parallel.

The base of an NPN transistor 197 , which has a grounded emitter, is connected to the cathode of the Zener diode 196 via a resistor 198 . A capacitor 199 and a resistor 200 are connected in parallel between the base and the emitter of the transistor 197 .

The collector of transistor 197 is connected to the gate of a thyristor 202 and via a resistor 201 to the anode of the thyristor 202 . The cathode of the thyristor 202 is connected to the AC output line 113 ', and a resistor 203 and a capacitor 204 are connected in parallel between the gate and the cathode of the thyristor 202 .

The cathode of a diode 205 is connected to the anode of the thyristor 202 , and its anode is connected via a resistor 206 to the cathode of the thyristor 186 of the ignition circuit 111 .

In the ignition start circuit 117 , immediately after the light switch 112 is closed and before the lamp is lit, the terminal voltage of the capacitor 115 is zero, and the transistor 197 is turned off. The thyristor 202 is therefore in the ON state.

Accordingly, the capacitor 192 of the ignition circuit 111 is gradually charged in a half-wave period of the AC signal of the high-frequency amplification stage 110 .

The terminal voltage of the capacitor 192 is determined by a circuit which is formed by the Zener diode 189 and opponents 188 and 190 . When this terminal voltage increases and zener diode 189 is made conductive, thyristor 186 is turned on and capacitor 192 is discharged.

The voltage generated at this time is raised by the trigger transformer 112 so that it is a trigger pulse of high voltage level. This trigger pulse is superimposed on a sinusoidal voltage from the high frequency booster circuit 110 , and the resultant voltage is applied to the lamp 116 to ignite it.

Thereafter, when the lamp is lit, a voltage of a predetermined value or higher is applied to the capacitor 115 , thereby turning on the transistor 197 ; This places the thyristor 202 in an OFF state, which stops the generation of the trigger pulse.

Since in the ignition starting circuit 117 described, the power supply voltage (that is, the voltage to be supplied to the transistor 197 and the thyristor 202 ) is obtained from the AC voltage output lines 113 and 113 ', it is possible to set the ignition circuit 111 and the ignition circuit 117 both on the same circuit board, and it is unnecessary to supply the power supply voltage from the power supply terminal 107 (or the power supply circuit connected to this terminal) to the ignition start circuit 117 , thereby realizing a structure which reduces the number of wiring operations required, and which is not easily affected by noise.

Control process

The control operation of the lamp circuit 101 will now be described in two cases: In the first case, in which the switching state is not abnormal and the lamp 116 is ignited immediately after the light switch 105 is turned on (hereinafter referred to as "the normal time") , and the second case in which an abnormality occurs in the switching state (hereinafter referred to as "the abnormal time").

Fig. 9 changes the output voltage V shows schematically ₀ (V) and output current I ₀ (A) of the booster circuit 109, the lamp current I _L (A), the lamp voltage V _L and the luminous flux L (lm) of the lamp 116 over time . The origin of the time axis t corresponds to the point in time at which the light switch 195 is closed. Fig. 10 shows a diagram of the relationship between the output voltage V ₀ on the abscissa and the output current I ₀ on the ordinate.

Normal time: First, a description regarding now given the environment at the time of cold start.

In this case, the capacitor 151 of the timing control circuit 122 is discharged immediately after the light switch 105 is closed, and the emitter potential of the transistor 148 is low. Accordingly, only the output voltage of the amplifier 135 is applied to the non-inverting input of the operational amplifier 140 in the output current detector 134 .

However, as shown in the solid line diagram in FIG. 9, after the lamp is ignited, the lamp voltage V _{L is} low, as is the output current I _{0 of} the DC booster circuit 109 .

In other words, the output voltage of the amplifier 135 (corresponding to the output current I ₀ ) is smaller than the reference voltage V ₂ from the reference voltage generator 143 , so that the output voltage of the operational amplifier 140 becomes a low level (L level).

Therefore, the PWM section 154 generates the control pulse Ps with a duty cycle specified by the output voltage of the operational amplifier 130 of the output voltage detector 129 , and this control pulse is sent through the gate drive circuit 121 to the FET 126 of the DC voltage booster circuit 109 .

The reference voltage V ₁ in the output voltage detector 129 is set to make the output voltage V _{0 of} the booster circuit 109 high (about 2.5 to 3 times the voltage obtained in the normal state), thereby maximizing the output voltage V ₀ .

The point a in Fig. 10 shows the state immediately after the lamp starts lighting. A control range A _V from point a to point b, to which the output current I ₀ gradually increases, the output voltage V _{0 being} approximately constant, is under the control of the output voltage detector 129 .

Then, the capacitor 151 is gradually charged, the emitter potential of the transistor 148 increases, and the potential of the non-inverting input of the operational amplifier 140 increases. If the time constant at this time is t ₁ , then the following applies

t₁ = (R ₁₅₂ // R ₁₅₃ ) × C ₁₅₁ ,

where "//" is a parallel summation of the resistors again gives.

When the potential reaches the level corresponding to the reference voltage V ₂ , the duty cycle of the control pulse Ps is determined by the output voltage of the operational amplifier 140 .

That is, since the duty cycle of the control pulse Ps decreases with an increase in the output voltage of the operational amplifier 140, the output voltage V ₀ , which has been kept at the maximum, decreases.

A control area A _I from point b to point d that passes through the peak point c of the output current I ₀ is controlled by the output current detector 134 .

When the capacitor 151 is fully charged, the transistor 148 is turned on, and its emitter potential is almost the same as the output voltage V _{0 of} the DC voltage booster circuit 109 . After that, the control goes into the constant power control mode.

Since the control is performed such that the sum of the output voltage V ₀ , voltage divided by the resistance ratio of the resistors 141 and 149 and the amplified output signal corresponding to the output current I ₀ becomes a constant value corresponding to V ₂ , that is, the constant power control realized in the form of a linear approximation at which V ₀ × I _{0 is} constant.

An area A _s from the point d to the point e in FIG. 10 is a constant power range where the lamp 116 is supplied with the rated power.

So the light flux L rises steeply, immediately after that Light is lit and shifts to the normal closed stood after going through an overshoot.

The operation to reignite the lamp 116 will now be described after it has been temporarily turned off.

During the time that the lamp is turned off, the charge stored in the capacitor 151 of the timing control circuit 122 is gradually discharged with a time constant t ₂ (= R ₁₅₃ × C ₁₅₁ ). This time constant t ₂ is determined according to the decrease rate of the temperature of the lamp after it has been turned off. Therefore, when the light switch 105 is closed again, the ignition process starts from the control area according to the terminal voltage of the capacitor 151 .

That is, the correct ignition control is carried out in accordance with the elapsed time it takes to re-ignite the lamp after it has been switched off once.

For example, in the case where the lamp is ignited again after a few tens of seconds have passed since the lamp was previously turned off, the lamp ignites from the operating point in the control area A _I and the control mode goes to constant power control. Therefore, the output voltage V ₀ and the output current I ₀ gradually decrease from the start of the lamp starting as shown by corresponding dotted lines in Fig. 9, and the luminous flux L from the lamp rises steeply at the beginning and becomes stable after going through an overshoot.

In the case in which the lamp 116 is re-ignited after being temporarily switched off for a few seconds, the glass bulb of the lamp 116 is still hot. As can be seen from the curves, as indicated in Fig. 9 by the two-dot chain lines, the lamp voltage V _{L is} high immediately after the lamp 116 is re-ignited, and the output current I _{0 of} the booster circuit 109 is high, causing a change to constant power control is effective, whereupon the light flux L becomes stable at the nominal power.

The timing control circuit 122 is provided to shorten the start time. That is, if timing control circuit 122 were not provided and the output voltage V ₀ of DC booster circuit 109 was applied directly to the non-inverting input of operational amplifier 140 through resistor 149 , constant power control would be performed from the start of lamp lighting are regardless of the physical conditions of the lamp, so that the light emission from the lamp would not progress through the control area A _V or A _I. This would delay the increase in light flux L.

Abnormal Time: The case where the Battery voltage is reduced.

When the battery voltage is equal to or greater than a predetermined value, e.g. 10 volts, the output voltage of voltage buffer 160 becomes higher than the input voltage of voltage buffer 146 in reference voltage generator 143 (with diode 161 turned off during this time), so that the value the reference voltage V _{2 is} determined by the resistors 144 and 144 'and the variable resistor 145 .

However, when the battery voltage is equal to or greater than 10 volts, the output voltage of the voltage buffer 160 becomes lower than the voltage from the reference voltage generator 143 and the diode 161 is turned on, thereby reducing the reference voltage V ₂ .

Therefore, a power smaller than the rated power (for example, 50 to 75%) is supplied to the lamp 116 in accordance with the decrease in the power supply voltage B. When the power supply voltage B is further decreased and the battery 102 cannot continue to ignite the lamp, it starts Low voltage reset circuit 124 a to we ken. In other words, if the battery voltage becomes equal to or less than a predetermined value, for example 7 volts, this voltage is determined by the voltage dividing resistors 171 and 172 and is compared by the comparator 169 with a given value. The comparator 169 then sends an L-level signal to the power cut-off relay circuit 106 to turn off the power supply to a (not shown) relay coil, which is connected to the DC voltage lines 104 and 104 ', whereupon the relay contact 106a opened becomes.

At the time when the battery voltage returns to 7 volts or above, the output signal of the comparator becomes an H level, and the relay contact 106 a is closed, so that the ignition process starts again.

The abnormality detector 124 has a circuit for detecting an abnormal condition, such as that the lamp 116 is unable to emit light due to normal deterioration at the end of its useful life, or that the output stage of the high frequency booster circuit 110 is on open circuit will. Although the structure of this circuit is omitted in detail, the abnormal state is maintained in this case unless the relay contact 106a is opened and the light switch 105a is temporarily opened and closed again.

business

With respect to the lamp circuit 101 described , the terminal potential of the capacitor 151 in the timing circuit 122 indicates the state after the lamp has been switched off, and the power can be supplied to the lamp accordingly. Therefore, it is possible to shorten the start-up time (or restart time) and stabilize the lamp ignition.

In particular, the cold start, for which the rise-up time is significant, the lamp excessive power is supplied to the time to the increase of the light flux ken to be Farming, by allowing the control heritage rich by CON A _V is the controlled by the output voltage detector 129 is after the ignition of the lamp begins and by the control area A _I , which is controlled by the output current detector 134 , and then by the transition to the normal state under constant power control A _{s is} approved. This control can improve the ignition characteristic.

Even if environmental conditions change or the load characteristic changes due to the replacement of the lamp or at the end of the lamp's useful life, the output voltage or current of the DC booster circuit 109 is determined and a product of these values (approximately the sum of the values) becomes made constant where is ensured by a constant power control in the normal state of the lamp.

A change in temperature can be caused by a change in the environmental conditions. This changes the inductance of the trigger transformer 112 or changes the inductance of the transformer 174 in the high-frequency booster circuit 110 or the electrostatic capacitances of the resonance capacitors 184 and 185 , thereby changing the oscillation frequency.

As described above, the lamp circuit includes the inven a DC voltage booster circuit to increase the Input voltage from a DC input terminal to to supply an output voltage that is converted to an AC voltage is converted, which to apply to a discharge lamp is also an output voltage detector for determination the output voltage of the DC booster circuit and for outputting a signal corresponding to the difference between the determined output voltage and a reference value, an output current detector for determining the output current with the booster circuit and for outputting a signal according to the difference between the determined output current and a reference value, a control circuit for generating supply of a control signal corresponding to signals from the  Output voltage detector and the output current detector for Applying the control signal to the booster circuit for control tion of their output voltage, and a timing device for applying a signal corresponding to the output voltage the booster circuit to the output current detector after expiration a period of time that is a turn-off time of the discharge lamp corresponds, and adding the signal to a signal corresponding to the Output current of the booster circuit corresponds to the over going to constant power control to do this To make the result of the addition constant, resulting in the ignition the discharge lamp when starting from a cool state Operation of the timing device after exercise of the tax transition to constant power control using effect of the nominal power, so the nominal power exceeding power to the output voltage detector and the output current detector is supplied.

According to the invention, therefore, at the time of the cold start Control after the light emission by the control gears by the output voltage detector and the off gear current detector are specified in the specified Order progresses, that is, the tax operations to Supply of power that exceeds the nominal power, over in the constant power control mode through the operation of the Timing device. At the time when the Entla lamp is ignited again, the output also voltage of the DC booster circuit accordingly the physical state of the lamp after it has been switched off controlled what is displayed by the timing device becomes. Accordingly, the light flux from the discharge lamp quickly reach the stable nominal level.

Claims (19)

1. lamp circuit for a discharge lamp for a driving takes to deliver a DC voltage booster circuit for raising (boosting) of an input voltage from a DC input terminal, an output voltage, which is converted into an AC voltage for application to a high-pressure discharge lamp, characterized by
a voltage detector ( 19 ) for determining the output voltage of the DC booster circuit ( 4 ),
a current detector ( 20 ) for determining the output current of the DC booster circuit ( 4 )
and a control circuit ( 10 ) for sending a control signal corresponding to signals from the voltage detector ( 19 ) and the current detector ( 20 ) to control the output voltage of the DC booster circuit ( 4 ), the control circuit ( 10 ) together with the voltage detector ( 19 ) and the current detector ( 20 ) form a feedback system for the DC booster circuit ( 4 ). 2. Lamp circuit according to claim 1, characterized by a delivery voltage detector to determine a to a DC input terminal applied DC input voltage voltage and for outputting a signal according to a ver reduction of the input DC voltage to the control circuit, so that the control circuit performs booster control to so the power to the discharge lamp based on the  Signal from the supply voltage detector lower than that To make rated power. 3. Lamp circuit according to claim 1, characterized in that the control circuit ( 10 ) generates a pulse duration modulation signal with a duty cycle corresponding to the signals from the voltage detector and the current detector and the pulse duration modulation signal to the DC voltage booster circuit ( 4 ) sends, to control their output voltage. 4. Lamp circuit according to claim 1, characterized by an ignition circuit ( 7 ) with a capacitor for determining the lamp current and a lamp current control, which is connected in series with the discharge lamp ( 8 ) in order to deliver a trigger pulse until the discharge lamp ( 8 ) after receiving an ignition start command, and by an ignition start circuit ( 9 ), which serves to decide on the basis of a detection voltage from the capacitor whether the discharge lamp ( 8 ) is ignited or not, and a signal from the ignition circuit ( 7 ) to send to stop the generation of the trigger pulse when the discharge lamp ( 8 ) is ignited. 5. Lamp circuit according to claim 1, characterized characterized in that the lighting circuit is a high-frequency Booster circuit for converting the output voltage of the DC booster circuit into an AC voltage comprises, and that a power supply voltage that a Ignition circuit is supplied to apply a trigger pulse ses to the discharge lamp until it is lit, and one Power supply voltage that an ignition start circuit leads to decide whether the discharge lamp is lit. det or not, and to allow the ignition circuit generates or stops generating the trigger pulse according to a decision result, be shared and  the common power supply voltage from an output line of the high-frequency booster circuit is obtained. 6. Lamp circuit according to claim 5, characterized in that the high-frequency booster circuit comprises:
one positive and one negative input terminal,
a transformer with a primary winding and a return winding,
a choke coil which is arranged between the positive input terminal and a center tap of the primary winding of the transformer,
a pair of active switching elements, which are each arranged between both ends of the primary winding of the transformer and the negative input terminal, for performing mutually opposite switching operations,
and a bias circuit with a constant current device connected to the end of the inductor located on one side of the transformer for supplying a predetermined bias based on a potential of a stage following the inductor to the active switching elements. 7. Lamp circuit according to claim 1, characterized by a high-frequency booster circuit for converting the output voltage from the DC booster circuit into an AC voltage, the high-frequency booster circuit to be summarized
one positive and one negative input terminal,
a transformer with a primary winding and a return winding,
a choke coil which is arranged between the positive input terminal and a center tap of the primary winding of the transformer,
a pair of active switching elements, which are each arranged between both ends of the primary winding of the transformer and the negative input terminal, for performing mutually opposite switching operations,
and a bias circuit with a constant current device connected to the end of the inductor located on one side of the transformer for supplying a predetermined bias based on a potential of a stage following the inductor to the active switching elements. 8. Lamp circuit according to claim 1, characterized by an abnormality detector for detecting an abnormality of the lighting circuit from a relationship between the Output voltage and the output current of the DC voltage Booster circuit and for outputting a signal for switching off power supply. 9. Lamp circuit according to claim 8, characterized net that the abnormality detector is a low voltage Reset circuit includes to apply an input DC voltage the DC voltage booster circuit to be switched off at determ that the DC input voltage is equal to or lower as a first predetermined value and to allow that the DC input voltage of the DC booster scarf device is fed again when determining that the input DC voltage is restored so that it is equal to or is greater than a second predetermined value. 10. Lamp circuit according to claim 9, characterized by a power cut-off circuit to allow and disable the supply of the input DC voltage to the DC voltage Booster circuit through a relay operation, the Power interruption circuit a relay switch for down switch the input DC voltage to the DC voltage Booster circuit includes when receiving a signal from the Low voltage reset circuit when the input is equal voltage at or below the first predetermined value falls.   11. A lamp circuit for a high pressure discharge lamp for a vehicle, characterized by a DC booster circuit for boosting the input voltage from a DC voltage input terminal to provide an output voltage which is converted into an AC voltage for application to a discharge lamp by
an output voltage detector ( 129 ) for determining the output voltage of the DC voltage booster circuit ( 109 ) and for outputting a signal corresponding to the difference between the determined output voltage and a reference value,
an output current detector ( 134 ) for determining the output current of the DC booster circuit ( 109 ) and for outputting a signal corresponding to the difference between the determined output current and a reference value,
a control circuit ( 118 ) for generating a control signal corresponding to signals from the output voltage detector ( 129 ) and the output current detector ( 134 ) and for applying the control signal to the DC booster circuit ( 109 ) to control its output voltage,
and timing means ( 122 ) for applying a signal corresponding to the output voltage of the DC booster circuit ( 109 ) to the output current detector ( 134 ) after a period corresponding to a turn-off time of the discharge lamp ( 116 ) and adding the signal to a signal corresponding to the output current the DC voltage booster circuit ( 109 ) for the transition to constant power control so as to make the addition result constant,
whereby upon ignition of the discharge lamp ( 116 ) starting from a cool state, the operation of the timer ( 122 ) causes the transition to constant power control which uses the rated power after performing control such that the output voltage detector ( 129 ) and the Output current detector ( 134 ) is supplied with a power exceeding the rated power. 12. Lamp circuit according to claim 11, characterized in that the timing device ( 122 ) comprises:
a time constant circuit with a discharge time constant for a lamp switch-off time and a charge time constant for a lamp switch-on time, the discharge time constant being different from the charge time constant,
and a switching device for determining whether or not, according to an output voltage of the time constant circuit, a signal corresponding to the output voltage of the DC booster circuit ( 109 ) is to be sent to the output current detector ( 134 ). 13. Lamp circuit according to claim 11, characterized by a supply voltage detector ( 123 ) for determining a DC input voltage applied to the DC input terminal and for changing the reference value of the output current detector ( 134 ) in accordance with a reduction in the DC input voltage, thereby a booster control in the manner ensure that the power to the discharge lamp ( 116 ) is made less than the nominal power. 14. Lamp circuit according to claim 11, characterized in that the control circuit ( 118 ) generates a pulse duration modulation signal with a duty cycle corresponding to the signals from the voltage detector ( 129 ) and the current detector ( 134 ) and the pulse duration modulation signal to the DC voltage -Booster circuit ( 109 ) sends to control their output voltage. 15. Lamp circuit according to claim 11, characterized by an ignition circuit ( 111 ) with a capacitor ( 115 ) for Lam penstromermittung and a lamp current control, which is connected in series with the discharge lamp ( 116 ) in order to deliver a trigger pulse until the discharge lamp ( 116 ) is ignited after receiving an ignition start command,
and by an ignition start circuit ( 117 ) serving to decide whether or not the discharge lamp ( 116 ) is lit based on a detection voltage from the capacitor ( 115 ) and to send a signal to the ignition circuit ( 111 ) to transmit the Set generation of the trigger pulse when the discharge lamp ( 116 ) is ignited. 16. Lamp circuit according to claim 11, characterized in that the lighting circuit comprises a high-frequency booster circuit ( 110 ) for converting the output voltage of the DC voltage booster circuit ( 109 ) into an AC voltage, and that a power supply voltage, the ignition circuit ( 111 ) is supplied to apply a trigger pulse to the discharge lamp ( 116 ) until it is ignited, and a power supply voltage which is supplied to an ignition start circuit ( 117 ) to decide whether the discharge lamp ( 116 ) is ignited or not and to allow that the ignition circuit ( 111 ) generates or stops generating the trigger pulse according to a decision result, be used in common and the common power supply voltage is obtained from an output line of the high frequency booster circuit ( 110 ). 17. Lamp circuit according to claim 11, characterized by a high-frequency booster circuit ( 110 ) for converting the output voltage of the DC booster circuit ( 109 ) into an AC voltage, the high-frequency booster circuit comprising ( 110 )
one positive and one negative input terminal,
a transformer ( 174 ) with a primary winding ( 174 a) and a feedback winding ( 177 ),
a choke coil ( 173 ) which is arranged between the positive input terminal (+) and a center tap of the primary winding ( 174 a) of the transformer ( 174 ),
a pair of active switching elements ( 181 , 181 '), each between the two ends of the primary winding ( 174 a) of the transformer ( 174 ) and the negative input terminal (G) are arranged to perform opposite switching operations,
and a bias circuit having a constant current device ( 182 , 182 ') connected to the end of the choke coil ( 173 ) located on one side of the transformer ( 174 ) for supplying a predetermined bias voltage which is at a potential of one based on the choke coil ( 173 ) following the active switching elements. 18. Lamp circuit according to claim 16, characterized in that the high-frequency booster circuit ( 110 ) comprises
one positive and one negative input terminal,
a transformer ( 174 ) with a primary winding ( 174 a) and a feedback winding ( 177 ),
a choke coil ( 173 ) which is arranged between the positive input terminal (+) and a center tap of the primary winding ( 174 a) of the transformer ( 174 ),
a pair of active switching elements ( 181 , 181 '), which are each arranged between both ends of the primary winding ( 174 a) of the transformer ( 174 ) and the negative input terminal (G), for performing mutually opposite switching operations,
and a bias circuit having a constant current device ( 182 , 182 ') connected to the end of the choke coil ( 173 ) located on one side of the transformer ( 174 ) for supplying a predetermined bias voltage which is at a potential of one based on the choke coil ( 173 ) following the active switching elements ( 181 , 181, ). 19. Lamp circuit according to claim 11, characterized by a voltage drop detector ( 123 ) for changing the reference value of the output current detector ( 134 ) in accordance with a reduction in the power supply voltage, thereby controlling the power supplied to the discharge lamp ( 116 ).